An essential glutamyl residue in EmrE, a multidrug antiporter from Escherichia coli

EmrE is an Escherichia coli 12-kDa protein that confers resistance to toxic compounds, by actively removing them in exchange with protons. The protein includes eight charged residues. Seven of these residues are located in the hydrophilic loops and can be replaced with either Cys or another amino acid bearing the same charge, without impairing transport activity. Glu-14 is the only charged residue in the membrane domain and is conserved in all the proteins of the family. We show here that this residue is the site of action of dicyclohexylcarbodiimide, a carbodiimide known to act in hydrophobic environments. When Glu-14 was replaced with either Cys or Asp, resistance was abolished. Whereas the E14C mutant displays no transport activity, the E14D protein shows efflux and exchange at rates about 30-50% that of the wild type. The maximal DeltapH-driven uptake rate of E14D is only 10% that of the wild type. The mutant shows a different pH profile in all the transport modes. Our results support the notion that Glu-14 is an essential part of a binding domain shared by substrates and protons but mutually exclusive in time. This notion provides the molecular basis for the obligatory exchange catalyzed by EmrE.     

Functional response of the small multidrug resistance protein EmrE to mutations in transmembrane helix 2

Escherichia coli EmrE is a small multidrug resistance protein encompassing four transmembrane (TM) sequences that oligomerizes to confer resistance to antimicrobials. Here we examined the effects on in vivo protein accumulation and ethidium resistance activity of single residue substitutions at conserved and variable positions in EmrE transmembrane segment 2 (TM2). We found that activity was reduced when conserved residues localized to one TM2 surface were replaced. Our findings suggest that conserved TM2 positions tolerate greater residue diversity than conserved sites in other EmrE TM sequences, potentially reflecting a source of substrate polyspecificity.     

Exploring the binding domain of EmrE, the smallest multidrug transporter

EmrE is a small multidrug transporter in Escherichia coli that extrudes various positively charged drugs across the plasma membrane in exchange with protons, thereby rendering cells resistant to these compounds. Biochemical experiments indicate that the basic functional unit of EmrE is a dimer where the common binding site for protons and substrate is formed by the interaction of an essential charged residue (Glu14) from both EmrE monomers. Previous studies implied that other residues in the vicinity of Glu14 are part of the binding domain. Alkylation of Cys replacements in the same transmembrane domain inhibits the activity of the protein and this inhibition is fully prevented by substrates of EmrE. To monitor directly the reaction we tested also the extent of modification using fluorescein-5-maleimide. While most residues are not accessible or only partially accessible, four, Y4C, I5C, L7C, and A10C, were modified at least 80%. Furthermore, preincubation with tetraphenylphosphonium reduces the reaction of two of these residues by up to 80%. To study other essential residues we generated functional hetero-oligomers and challenged them with various methane thiosulfonates. Taken together the findings imply the existence of a binding cavity accessible to alkylating reagents where at least three residues from TM1, Tyr40 from TM2, and Trp63 in TM3 are involved in substrate binding.     

Membrane topology of a multidrug efflux transporter, AcrB, in Escherichia coli.

AcrA/B in Escherichia coli is a multicomponent system responsible for intrinsic resistance to a wide range of toxic compounds, and probably cooperates with the outer membrane protein TolC. In this study, acrAB genes were cloned from the E. coli W3104 chromosome. To determine the topology of the inner membrane component AcrB, we employed a chemical labeling approach to analyse mutants of AcrB in which a single cysteine residue had been introduced. The cysteine-free AcrB mutant, in which the two intrinsic Cys residues were replaced by Ala, retained full drug resistance. We constructed 33 cysteine mutants in which a single cysteine was introduced into each putative hydrophilic loop region of the cysteine-free AcrB. The binding of [(14)C]N-ethylmaleimide (NEM) to the Cys residue and the competition of NEM binding with the binding of a membrane-impermeant maleimide, 4-acetamide-4'-maleimidylstilbene-2,2'-disulfonic acid (AMS), in intact cells were investigated. The results revealed that the N- and C-terminals are localized on the cytoplasmic surface of the membrane and the two large loops are localized on the periplasmic surface of the membrane. The results supported the 12-membrane-spanning structure of AcrB. Three of the four short periplasmic loop regions were covered by the two large periplasmic loop domains and were not exposed to the water phase until one of the two large periplasmic loops was removed.     

Structure-function relationship of the fifth transmembrane domain in the Na+/H+ antiporter of Helicobacter pylori: Topology and function of the residues, including two consecutive essential aspartate residues

We examined the structure-function relationships of residues in the fifth transmembrane domain (TM5) of the Na+/H+ antiporter A (NhaA) from Helicobacter pylori (HP NhaA) by cysteine scanning mutagenesis. TM5 contains two aspartate residues, Asp-171 and Asp-172, which are essential for antiporter activity. Thirty-five residues spanning the putative TM5 and adjacent loop regions were replaced by cysteines. Cysteines replacing Val-162, Ile-165, and Asp-172 were labeled with NEM, suggesting that these three residues are exposed to a hydrophilic cavity within the membrane. Other residues in the putative TM domain, including Asp-171, were not labeled. Inhibition of NEM labeling by the membrane impermeable reagent AMS suggests that Val-162 and Ile-165 are exposed to a water filled channel open to the cytoplasmic space, whereas Asp-172 is exposed to the periplasmic space. D171C and D172C mutants completely lost Na+/H+ and Li+/H+ antiporter activities, whereas other Cys replacements did not result in a significant loss of these activities. These results suggest that Asp-171 and Asp-172 and the surrounding residues of TM5 provide an essential structure for H+ binding and Na+ or Li+ exchange. A168C and Y183C showed markedly decreased antiporter activities at acidic pH, whereas their activities were higher at alkaline pH, suggesting that the conformation of TM5 also plays a crucial role in the HP NhaA-specific acidic pH antiporter activity.     

Cysteine-scanning mutagenesis around transmembrane segment VI of Tn10-encoded metal-tetracycline/H(+) antiporter

Each amino acid in putative transmembrane helix VI and its flanking regions, from Ser-156 to Thr-185, of a Cys-free mutant of the Tn10-encoded metal-tetracycline/H(+) antiporter (TetA(B)) was individually replaced by Cys. All of the cysteine-scanning mutants showed a normal level of tetracycline resistance except for the S156C mutant, which showed moderate resistance, indicating that there is no essential residue located in this region. All 20 mutants from S159C to W178C showed no reactivity with N-ethylmaleimide (NEM), whereas the mutants of the flanking regions from S156C to H158C and F179C to T185C were highly or moderately reactive with NEM. These results indicate that like transmembrane helices III and IX, the transmembrane helix VI comprising residues Ser-159-Trp-178 is totally embedded in the hydrophobic environment.     

The sucrose permease of Escherichia coli: functional significance of cysteine residues and properties of a cysteine-less transporter

The sucrose (CscB) permease belongs to the oligosaccharide:H(+) symporter family of the Major Facilitator Superfamily and is homologous to the lactose permease from Escherichia coli. Sucrose transport in cells expressing sucrose permease is completely inhibited by N-ethylmaleimide (NEM), suggesting that one or more of the seven native Cys residues may be important for transport. In this paper, each Cys residue was individually replaced with Ser, and transport activity, membrane expression, and NEM sensitivity are documented. All seven single Cys-->Ser mutants are expressed normally in the membrane and catalyze sucrose transport with activities ranging from 80% to 180% of wild type. Six of the seven Ser mutants are completely inactivated by NEM, while Cys122-->Ser permease is insensitive to the sulfhydryl reagent, indicating that NEM inhibition results from alkylation of Cys122. Subsequently, a sucrose permease devoid of Cys residues (Cys-less) was constructed in which all Cys residues were replaced with Ser simultaneously by using a series of overlap-extension PCRs. Membrane expression and kinetic parameters for Cys-less [K(m) 4.8 mM, V(max) 192 nmol min(-1) (mg of protein)(-1)] are essentially identical to those of wild type [K(m) 5.4 mM, V(max) 196 nmol min(-1) (mg of protein)(-1)]. However, Cys-less permease catalyzes sucrose accumulation to steady-state levels that are approximately 2-fold higher than those of wild type. As anticipated, Cys-less permease is completely resistant to NEM inhibition. The observations demonstrate that Cys residues play no functional role in sucrose permease. Furthermore, the approach described to create the Cys-less transporter is generally applicable to other proteins. An application of Cys-less permease in the study of the substrate binding site is presented in the accompanying paper.     

Identification of a glycine motif required for packing in EmrE, a multidrug transporter from Escherichia coli

Glycine residues may play functional and structural roles in membrane proteins. In this work we studied the role of glycine residues in EmrE, a small multidrug transporter from Escherichia coli. EmrE extrudes various drugs across the plasma membrane in exchange with protons and, as a result, confers resistance against their toxic effects. Each of 12 glycine residues was replaced by site-directed mutagenesis. Four of the 12 glycine residues in EmrE are evolutionary conserved within the small multidrug resistance family of multidrug transporters. Our analysis reveals that only two (Gly-67 and Gly-97) of these four highly conserved residues are essential for transporter activity. Moreover, two glycine positions that are less conserved, Gly-17 and Gly-90, demonstrate also a nil phenotype when substituted. Our present results identifying Gly-17 and Gly-67 as irreplaceable reinforce the importance of previously defined functional clusters. Two essential glycine residues, Gly-90 and Gly-97, form a protein motif in which glycine residues are separated by six other residues (GG7). Upon substitution of glycine in these positions, the protein ability to form dimers is impaired as evaluated by cross-linking and pull-down experiments.     

Identification of tyrosine residues critical for the function of an ion-coupled multidrug transporter

Aromatic residues may play several roles in integral membrane proteins, including direct interaction with substrates. In this work, we studied the contribution of tyrosine residues to the activity of EmrE, a small multidrug transporter from Escherichia coli that extrudes various drugs across the plasma membrane in exchange with protons. Each of five tyrosine residues was replaced by site-directed mutagenesis. Two of these residues, Tyr-40 and Tyr-60, can be partially replaced with hydroxyamino acids, but in the case of Tyr-40, replacement with either Ser or Thr generates a protein with modified substrate specificity. Replacement of Tyr-4 with either Trp or Phe generates a functional transporter. A Cys replacement at this position generates an uncoupled protein; it binds substrate and protons and transports the substrate downhill but is impaired in uphill substrate transport in the presence of a proton gradient. The role of these residues is discussed in the context of the published structures of EmrE.     

Structural analysis of synthetic peptide fragments from EmrE,a multidrug resistance protein,in a membrane-mimetic environment

EmrE, a multidrug resistance protein from Escherichia coli, renders the bacterium resistant to a variety of cytotoxic drugs by active translocation out of the cell. The 110-residue sequence of EmrE limits the number of structural possibilities that can be envisioned for this membrane protein. Four helix bundle models have been considered [Yerushalmi, H., Lebendiker, M., and Schuldiner, S. (1996) J. Biol. Chem. 271, 31044-31048]. The validity of EmrE structural models has been probed experimentally by investigations on overlapping peptides (ranging in length from 19 to 27 residues), derived from the sequence of EmrE. The choice of peptides was made to provide sequences of two complete, predicted transmembrane helices (peptides H1 and H3) and two helix-loop-helix motifs (peptides A and B). Peptide (B) also corresponds to a putative hairpin in a speculative beta-barrel model, with the "Pro-Thr-Gly" segment forming a turn. Structure determination in SDS micelles using NMR indicates peptide H1 to be predominantly helical, with helix boundaries in the micellar environment corroborating predicted helical limits. Peptide A adopts a helix-loop-helix structure in SDS micelles, and peptide B was also largely helical in micellar environments. An analogue peptide, C, in which the central "Pro-Thr-Gly" was replaced by "(D)Pro-Gly" displays local turn conformation at the (D)Pro-Gly segment, but neither a continuous helical stretch nor beta-hairpin formation was observed. This study implies that the constraints of membrane and micellar environments largely direct the structure of transmembrane peptides and proteins and study of judiciously selected peptide fragments can prove useful in the structural elucidation of membrane proteins.     

The role of helix VIII in the lactose permease of Escherichia coli: II. Site-directed sulfhydryl modification.

Cys-scanning mutagenesis of putative transmembrane helix VIII in the lactose permease of Escherichia coli (Frillingos S. Ujwal ML, Sun J, Kaback HR, 1997, Protein Sci 6:431-437) indicates that, although helix VIII contains only one irreplaceable residue (Glu 269), one face is important for active lactose transport. In this study, the rate of inactivation of each N-ethylmaleimide (NEM)-sensitive mutant is examined in the absence or presence of beta, D-galactopyranosyl 1-thio-beta,D-galactopyranoside (TDG). Remarkably, the analogue affords protection against inactivation with mutants Val 264-->Cys, Gly 268-->Cys, and Asn 272-->Cys, and alkylation of these single-Cys mutants in right-side-out membrane vesicles with [14C]NEM is attenuated by TDG. In contrast, alkylation of Thr 265-->Cys, which borders the three residues that are protected by TDG, is enhanced markedly by the analogue. Furthermore, NEM-labeling in the presence of the impermeant thiol reagent methanethiosulfonate ethylsulfonate demonstrates that ligand enhances the accessibility of position 265 to solvent. Finally, no significant alteration in NEM reactivity is observed for mutant Gly 262-->Cys, Glu 269-->Cys, Ala 273-->Cys, Met 276-->Cys, Phe 277-->Cys, or Ala 279-->Cys. The findings indicate that a portion of one face of helix VIII (Val 264, Gly 268, and Asn 272), which is in close proximity to Cys 148 (helix V), interacts with substrate, whereas another position bordering these residues (Thr 265) is altered by a ligand-induced conformational change.     

Complete cysteine-scanning mutagenesis and site-directed chemical modification of the Tn10-encoded metal-tetracycline/H+ antiporter

Bacterial Tn10-encoded metal-tetracycline/H(+) antiporter was the first found drug exporter and has been studied as a paradigm of antiporter-type major facilitator superfamily transporters. Here the 400 amino acid residues of this protein were individually replaced by cysteine except for the initial methionine. As a result, we could obtain a complete map of the functionally or structurally important residues. In addition, we could determine the precise boundaries of all the transmembrane segments on the basis of the reactivity with N-ethylmaleimide (NEM). The NEM binding results indicated the presence of a transmembrane water-filled channel in the transporter. The twelve transmembrane segments can be divided into three groups; four are totally embedded in the hydrophobic interior, four face a putative water-filled channel along their full length, and the remaining four face the channel for half their length, the other halves being embedded in the hydrophobic interior. These three types of transmembrane segments are mutually arranged with a 4-fold symmetry. The competitive binding of membrane-permeable and -impermeable SH reagents in intact cells indicates that the transmembrane water-filled channel has a thin barrier against hydrophilic molecules in the middle of the transmembrane region. Inhibition and stimulation of NEM binding in the presence of tetracycline reflects the substrate-induced protection or conformational change of the Tn10-encoded metal-tetracycline/H(+) antiporter. The mutations protected from NEM binding by tetracycline were mainly located around the permeability barrier in the N-terminal half, suggesting the location of the substrate binding site.     

Cysteine-scanning mutagenesis of transmembrane segments 4 and 5 of the Tn10-encoded metal-tetracycline/H+ antiporter reveals a permeability barrier in the middle of a transmembrane water-filled channel

Cysteine-scanning mutants as to putative transmembrane segments 4 and 5 and the flanking regions of Tn10-encoded metal-tetracycline/H(+) antiporter (TetA(B)) were constructed. All mutants were normally expressed. Among the 57 mutants (L99C to I155C), nine conserved arginine-, aspartate-, and glycine-replaced ones exhibited greatly reduced tetracycline resistance and almost no transport activity, and five conserved glycine- and proline-replaced mutants exhibited greatly reduced tetracycline transport activity in inverted membrane vesicles despite their high or moderate drug resistance. All other cysteine-scanning mutants retained normal drug resistance and normal tetracycline transport activity except for the L142C and I143C mutants. The transmembrane (TM) regions TM4 and TM5 were determined to comprise 20 amino acid residues, Leu-99 to Ile-118, and 17 amino acid residues, Ala-136 to Ala-152, respectively, on the basis of N-[(14)C]ethylmaleimide ([(14)C]NEM) reactivity. The NEM reactivity patterns of the TM4 and TM5 mutants were quite different from each other. TM4 could be divided into two halves, that is, a NEM nonreactive periplasmic half and a periodically reactive cytoplasmic half, indicating that TM4 is tilted toward a water-filled transmembrane channel and that only its cytoplasmic half faces the channel. On the other hand, NEM-reactive mutations were observed periodically (every two residues) along the whole length of TM5. A permeability barrier for a membrane-impermeable sulfhydryl reagent, 4-acetamido-4'-maleimidylstilbene-2,2'-disulfonic acid, was present in the middle of TM5 between Leu-142 and Gly-145, whereas all the NEM-reactive mutants as to TM4 were not accessible to 4-acetamido-4'-maleimidylstilbene-2,2'-disulfonic acid, indicating that the channel-facing side of TM4 is located inside the permeability barrier. Tetracycline protected the G141C mutant from the NEM binding, whereas the other mutants in TM4 and TM5 were not protected by tetracycline.     

The first cytoplasmic loop of the mannitol permease from Escherichia coli is accessible for sulfhydryl reagents from the periplasmic side of the membrane

The mannitol permease (EII(Mtl)) from Escherichia coli couples mannitol transport to phosphorylation of the substrate. Renewed topology prediction of the membrane-embedded C domain suggested that EII(Mtl) contains more membrane-embedded segments than the six proposed previously on the basis of a PhoA fusion study. Cysteine accessibility was used to confirm this notion. Since cysteine 384 in the cytoplasmic B domain is crucial for the phosphorylation activity of EII(Mtl), all cysteine mutants contained this activity-linked cysteine residue in addition to those introduced for probing the membrane topology of the protein. To distinguish between the activity-linked cysteine and the probed cysteine, either trypsin was used to specifically digest the two cytoplasmic domains (A and B), thereby removing Cys384, or Cys384 was protected by phosphorylation from alkylation by N-ethylmaleimide (NEM). Our data show that upon phosphorylation EII(Mtl) undergoes major conformational changes, whereby residues in the putative first cytoplasmic loop become accessible to NEM. Other residues in this loop were accessible to NEM in intact cells and inside-out membrane vesicles, but cysteine residues at these positions only reacted with the membrane-impermeable sulfhydryl reagent from the periplasmic side of the protein. These and other results suggest that the predicted loop between TM2 and TM3 may fold back into the membrane and form part of the translocation path.     

Cysteine 532 and cysteine 545 are the N-ethylmaleimide-reactive residues of the Neurospora plasma membrane H+-ATPase

Previous studies from this laboratory (Brooker, R. J., and Slayman, C. W. (1983) J. Biol. Chem. 258, 222-226; Davenport, J. W., and Slayman, C. W. (1988) J. Biol. Chem. 263, 16007-16013) have used the sulfhydryl reagent N-ethylmaleimide (NEM) to define two sites on the Neurospora plasma membrane H+-ATPase: a "fast" site which reacts in several minutes with no loss of enzymatic activity and a "slow" site which reacts in tens of minutes to produce complete inactivation of the enzyme. The slow site is protected when MgATP or MgADP is bound to the catalytic site of the ATPase. The present study demonstrates that the fluorescent reagent 5-[2-iodoacetamido)ethyl)-1-aminonaphthalenesulfonic acid (IAEDANS) can be used to label five of the eight cysteine residues of the Neurospora ATPase (Cys376, Cys409, Cys472, Cys532, Cys545). Tryptic peptides bearing those residues have been purified by high performance liquid chromatography and located within the known primary structure of the ATPase by amino acid analysis and/or sequencing. By pretreating the enzyme with NEM in the presence or absence of MgADP before incubation with IAEDANS, it has been possible to identify the fast NEM site as Cys545 and the slow MgADP-protectable NEM site as Cys532. Both residues lie within the central hydrophilic domain of the protein, close to a highly conserved stretch of amino acids that may be involved in nucleotide binding. However, all five IAEDANS-reactive cysteines can be nearly completely modified by the less bulky sulfhydryl reagent methyl methanethiosulfonate with less than 20% inhibition of enzyme activity; thus, none of the five cysteines can be considered to play a direct role in the reaction cycle of the ATPase.     

A sulfhydryl presumed essential is not required for catalysis by an aminoacyl-tRNA synthetase

Several aminoacyl-tRNA synthetases are sensitive to reagents that modify sulfhydryl groups. We report here the significance of N-ethylmaleimide (NEM)-mediated inactivation of Escherichia coli glycyl-tRNA synthetase, and alpha 2 beta 2 enzyme. We confirmed earlier observations that NEM abolishes synthetase-catalyzed aminoacylation with pseudo-first order kinetics and provided a second method of proof that the site of inactivation is located in the beta-subunit. Using oligonucleotide-directed mutagenesis of the glyS gene, each beta-subunit cysteine codon (positions 98, 395, and 450) was replaced, individually, by an alanine codon. The three resulting mutant proteins are each active in vivo, and their in vitro aminoacylation activities are comparable to that of the native enzyme. A mutant incorporating all three amino acid substitutions is also active in vivo and in vitro. These results establish conclusively that a beta-subunit cysteine thiol is not required for the catalysis of aminoacylation. The Cys98----Ala and Cys450----Ala mutants are inactivated by NEM with the same kinetics as the wild-type protein. However, the Cys395----Ala mutant is refractory to NEM. This suggests that NEM inactivation of the native enzyme is due to alkylation of Cys395. Aware that inactivation may result from steric effects, we constructed a mutant with a bulkier amino acid residue at position 395 (Cys395----Gln). The aminoacylation activity of this protein is less than 10% of that of the wild-type enzyme. The glutamine substitution affects only the tRNA-dependent step of the reaction--the rate of glycyl adenylate synthesis is not lowered. In these features, the mutant resembles the NEM-inactivated protein. We propose that the NEM sensitivity of glycyl-tRNA synthetase, and possibly of other synthetases, arises from steric or conformational effects of the alkylated cysteine side chain.     

Multimeric forms of the small multidrug resistance protein EmrE in anionic detergent

Escherichia coli multidrug resistance protein E (EmrE) is a four transmembrane α-helix protein, and a member of the small multidrug resistance protein family that confers resistance to a broad range of quaternary cation compounds (QCC) via proton motive force. The multimeric states of EmrE protein during transport or ligand binding are variable and specific to the conditions of study. To explore EmrE multimerization further, EmrE extracted from E. coli membranes was solubilized in anionic detergent, sodium dodecyl sulphate (SDS), at varying protein concentrations. At low concentrations (≤ 1 μM) in SDS-EmrE is monomeric, but upon increasing EmrE concentration, a variety of multimeric states can be observed by SDS-Tricine polyacrylamide gel electrophoresis (PAGE). Addition of the (QCC), tetraphenyl phosphonium (TPP), to SDS-EmrE samples enhanced EmrE multimer formation using SDS-Tricine PAGE. The relative shapes of EmrE multimers in SDS with or without TPP addition were determined by small angle neutron scattering (SANS) analysis and revealed that EmrE dimers altered in conformation depending on the SDS concentration. SANS analysis also revealed that relative shapes of larger EmrE multimers (≥ 100 nm sizes) altered in the presence of TPP. Circular dichroism spectropolarimetry displayed no differences in secondary structure under the conditions studied. Fluorescence spectroscopy of SDS-EmrE protein demonstrated that aromatic residues, Trp and Tyr, are more susceptible to SDS concentration than TPP addition, but both residues exhibit enhanced quenching at high ligand concentrations. Hence, EmrE forms various multimers in SDS that are influenced by detergent concentration and TPP substrate addition.     

The Role of Cysteines and Histidins of the Norepinephrine Transporter

The thiol reagent N-ethylmaleimide (NEM) is known to inhibit irreversibly ligand binding by the norepinephrine transporter (NET), while the simultaneous presence of NET substrates or ligands protects from this inhibition. Therefore, cysteine residues located within the substrate binding pocket of the NET were assumed to play an important role in ligand binding. To examine which (if any) of the 10 cysteines (Cys) of the human (h) NET might be involved in transport and/or binding function, we mutated all hNET cysteines to alanine. Using transfected HEK293 cells we studied NEM effects on the hNET with respect to [³H]nisoxetine binding. Two cysteines (Cys176 and Cys185) within the extracellular loop of the NET have been proposed to form a disulfide bond. We could demonstrate that this is of crucial importance as corresponding hNET mutants, in which these cysteines have been replaced, showed a lack of plasma membrane expression. However, due to their oxidized state in the native NET protein, Cys176 and Cys185 may not be targets for NEM. All other Cys-to-Ala hNET mutants were fully active and showed no change in inhibition of [³H]nisoxetine binding by NEM. These observations clearly exclude cysteines as being involved in hNET ligand binding. Since NEM also interacts with histidin (His), we mutated all 13 histidins of the hNET to alanine and examined the NET mutants in functional and binding assays. His222 within the large extracellular loop of the transporter was identified as an interaction partner of NEM since in the corresponding hNET mutant NEM exhibited a significantly reduced inhibitory potency. Furthermore, we could show that histidins in position 296, 370 and 372 are important for nisoxetine binding, while His220, 441, 598 and 599 are crucial for plasma membrane expression of the hNET.     

Electron crystallography reveals plasticity within the drug binding site of the small multidrug transporter EmrE

EmrE is a Small Multidrug Resistance transporter (SMR) family member that mediates counter transport of protons and hydrophobic cationic drugs such as tetraphenylphosphonium (TPP⁺), ethidium, propidium and dequalinium. It is thought that the selectivity of the drug binding site in EmrE is defined by two negatively charged glutamate residues within a hydrophobic pocket formed from six of the α-helices, three from each monomer of the asymmetric EmrE homodimer. It is not apparent how such a binding pocket accommodates drugs of various sizes and shapes or whether the conformational changes that occur upon drug binding are identical for drugs of diverse chemical nature. Here, using electron cryomicroscopy of EmrE two-dimensional crystals we have determined projection structures of EmrE bound to three structurally different planar drugs, ethidium, propidium and dequalinium. Using image analysis and rigorous comparisons between these density maps and the density maps of the ligand-free and TPP⁺-bound forms of EmrE, we identify regions within the transporter that adapt differentially depending on the type of ligand bound. We show that all three planar drugs bind at the same pocket within the protein as TPP⁺. Furthermore, our analysis indicates that, while retaining the overall fold of the protein, binding of the planar drugs is accompanied by small rearrangements of the transmembrane domains that are different to those that occur when TPP⁺ binds. The regions in the EmrE dimer that are remodelled surround the drug binding site and include transmembrane domains from both monomers.